Apparatus for separating melon flesh from rind

ABSTRACT

An apparatus for preparing a melon juice concentrate, such as watermelon juice concentrate, includes a finisher with brushes for separating melon flesh from melon rind including leaving at least 1/16 inch flesh on the rind and screens for separating juice from flesh. The apparatus also includes a steamer to reduce bacteria count on whole melon, a chopper for chopping melons into pieces less than about 16 inches square, an extractor for extracting juice from the flesh, and an evaporator for concentrating melon juice to form melon juice concentrate. The steamer includes a cylinder frame, steam jets directing steam through apertures in the cylinder frame at whole melon therein, and a motivator to move the whole melon along the cylinder frame. The apparatus can also process cantaloupe, honeydew melon, and other melon.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of application Ser. No. 11/469,168, filed on Aug. 31, 2006, entitled APPARATUS FOR SEPARATING MELON FLESH FROM RIND, the entire disclosure of which is incorporated herein by reference. U.S. patent application Ser. No. 11/469,168 claims benefit of provisional application Ser. No. 60/712,985, filed Aug. 31, 2005, entitled WATERMELON EXTRACTS AND PROCESS OF PRODUCING THE WATERMELON EXTRACTS, the entire contents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

The present invention relates to an apparatus for producing melon juice and/or juice concentrate.

Natural watermelon extract, including watermelon juice and watermelon juice concentrate, should ideally have a strong watermelon flavor identity and a red color. Unfortunately, to date, previously produced watermelon extract exhibited an “off” flavor primarily as a result of a fishy odor and flavor. It is presently believed that previously produced juices have been produced using the entire watermelon, including the rind, and typically have an amber or yellow color.

Some currently available watermelon juice products include additives, such as colorants, sugars, and flavors to mask the fishy taste and odor. Some watermelon juice products also include thickening agents. One such thickening agent is carrageenan, a phycocolloid derived from seaweed.

The red flesh portion of the watermelon is the portion consumers typically eat. Therefore, watermelon juice is preferably red in color. The red color desired in watermelon juice can be both observed and quantified. Cloudy watermelon juice can be measured using an instrument called a HUNTER™ colorimeter. The HUNTER™ colorimeter designates color measurements into three categories, L, A and B, and assigns a value to each. The L value measures the “brightness” of the juice, the A value measures the “redness,” and the B value measures the “brown” of a juice. Using these values, different cloudy watermelon juices can be compared and contrasted on a quantitative basis, providing real numbers in the comparison.

There are generally two types of watermelon juice, cloudy and clarified. A cloudy fruit juice is generally unfiltered with the cloudiness coming from natural fruit material. In the case of watermelon juice, the cloudiness is primarily due to small pieces of flesh remaining in the cloudy juice. Clarified or clear juice is generally derived from cloudy juice. A HUNTER™ colorimeter is not typically used to quantify color in clarified watermelon juice. Instead, color of a clarified juice extract is typically expressed at percent transmittance at a particular light wavelength.

There is a significant need for a high-quality manufacturable, natural watermelon extract, such as a juice or a concentrate, having a red color and a strong watermelon flavor identity. There is also a need for an apparatus and a method of producing such an extract. More broadly, there is a significant need for melon extract, such as a juice or concentrate from watermelon, cantaloupe, honeydew melon, or similar fruit with rind.

SUMMARY OF THE INVENTION

In one aspect of the present invention, an apparatus for preparing a melon juice includes a separator finisher for automatically separating melon flesh from watermelon rind while leaving a predetermined depth of flesh attached to the rind.

In another aspect of the present invention, an apparatus for preparing a melon juice product includes a separator with brushes configured to separate melon flesh from melon rind.

These and other features, advantages, and objects of the present invention will be further understood and appreciated by those skilled in the art by reference to the following specification, claims, and appended drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in, and constitute a part of, the specification illustrate several embodiments of the invention and together with the description, serve to explain the objects, advantages, and principles of the invention.

FIG. 1 is a flow diagram illustrating a process of producing a cloudy watermelon concentrate in accordance with the present invention;

FIG. 2 is a perspective view of a steamer of the present invention used in the process of the present invention;

FIG. 2A is a cross-sectional view of the steamer of the present invention showing an outer cylinder, auger, and steam pipes inside the steamer of FIG. 2 at different levels;

FIG. 2B is an expanded view of the steam pipes of the steamer of FIG. 2A;

FIG. 2C is an expanded view of an outer cylinder as shown in the steamer of FIG. 2A;

FIG. 2D is an expanded view of the reverse auger of a steamer of FIG. 2A;

FIG. 2E is a side elevational view of a steamer of the present invention;

FIG. 3 is an elevated perspective view of a chopping apparatus of the present invention;

FIG. 4 is a perspective view of a first finisher of the present invention;

FIG. 5 is a cross-sectional view of the first finisher of the present invention;

FIG. 6 is an expanded view of the inside of the first finisher of the present invention showing brushes, an inside screen, and rotating arms;

FIG. 6A is an expanded view of the brushes, inside screen, and rotating arm of a first finisher of the present invention, as shown in FIG. 6;

FIG. 6B is an elevational view of a second finisher of the present invention;

FIG. 6C is an elevational view of a filter of the present invention;

FIG. 7 is a plan view of the process of a preferred embodiment of the present invention; and

FIG. 8 is a flow diagram illustrating a process of producing clarified watermelon concentrate in accordance with the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENT

FIG. 1 generally shows a process for producing a cloudy watermelon juice extract, in particular a concentrate, in accordance with the present invention. The process generally includes steaming whole watermelons that are introduced into a steamer 10 where steam is applied to the exterior surface of the whole watermelons. Next, the steamed whole watermelons are typically transferred to a chopper 40. The chopper serves to reduce the size of the watermelon pieces. These watermelon pieces typically comprise pieces of watermelon flesh only, pieces of watermelon rind only, and pieces of watermelon flesh attached to watermelon rind. At this point in the process, the watermelon flesh includes watermelon juice. The watermelon pieces are sent to a receiving tank 50. From the receiving tank, the watermelon pieces go to a first finisher 60, where the watermelon flesh is substantially separated from the watermelon rind. In the first finisher 60, an at least portion of watermelon juice is extracted from the watermelon flesh to form a mixture. The substantially separated watermelon flesh and juice mixture is transferred to a second finisher 100. The watermelon rind goes to the waste auger 150, where it is removed and sent for disposal 160. The second finisher 100 generally substantially removes any watermelon seeds present in the mixture of watermelon flesh and juice. Once the seeds are removed, the mixture of watermelon flesh and juice is sent to a filter device 110, where the watermelon juice is substantially separated from the watermelon flesh. The watermelon juice is transferred to holding tanks 120 and 130 where edible acid is typically added to adjust the pH of the juice. Once the desired pH level is achieved, the watermelon juice is optionally sent to an evaporator 140, where water, typically substantially all of the water, is removed to form a watermelon concentrate. The watermelon concentrate is packaged 170 and sent out as finished product.

FIG. 2 shows the steamer 10 of the present invention. The steamer typically includes a plurality of vertical supports 12 and cross support members 14, which support the housing 16 of the steam cylinder assembly 18. The housing 16 has removable access doors 20, which are primarily shown as cut away portions in FIG. 2. The support members 12, 14, housing 16, and access doors 20 are typically manufactured from steel. The steamer 10 typically further includes steam supply lines 22, which feed the steam lines 24 typically disposed in a parallel manner in the bottom quarter of the housing 16 and spaced below the steamer cylinder assembly 18 with the steam jets 26 directed substantially upward. The steam lines 24 and jets 26 could be positioned anywhere in the housing 16 so long as steam is applied to the watermelons traversing the steam cylinder assembly 18.

The steam cylinder assembly 18 is typically mounted within the housing 16 and includes a main cylinder frame 28 that typically is mounted above the steam lines on roller supports 29, which rotate and are mounted on the inside surface of the housing 16. The steam cylinder assembly 18 is operably connected, typically by a drive belt assembly, to a motor 30, which provides the drive force necessary to rotate the steam cylinder assembly 18. The belt is typically frictionally engaged to the outside surface of main cylinder frame 28. The main cylinder frame 28 typically has a plurality of apertures 27 (FIG. 2A). The apertures 27 as shown in FIG. 2C are typically arranged around the circumference of the cylinder and form parallel rings which extend down the length of the cylinder. Typically, the apertures 27 are from about 2 inches to about 8 inches wide and from about 4 inches to about 14 inches long. More typically, the apertures are from about 2½ inches to about 6 inches wide and from about 8 inches to about 12 inches long. Most typically, the apertures are about 3⅛ inches wide and about 11 inches long. The parallel rings of the apertures are typically spaced from about 1 inch to about 12 inches apart, more typically from about 7 inches to about 11 inches apart, and most typically about 8⅞ inches apart. While the arrangement of the apertures 27 in the main cylinder frame 28 of the steamer 10 described is that of a preferred embodiment, those skilled in the art will recognize that other arrangements will also work in the steamer of the present invention. The preferred dimensions of the apertures prevent watermelon fragments that may break off in the steamer from falling through the apertures. The apertures 27 further function to provide access points for the steam from the steam lines to contact the exterior surface of the watermelon traversing the main cylinder frame.

Typically, the main cylinder frame 28 has a length of from about 18 feet to about 19 feet, and most typically has a length of 18.5 feet. The main cylinder frame 28 typically has a diameter of from about 24 inches to about 36 inches, more typically from about 30 inches to about 34 inches, and most typically a diameter of about 32 inches.

As shown in FIGS. 2A, 2D, and 2E, inside the main cylinder frame 28 includes a reverse auger 31. In operation, the whole watermelons are introduced into one end of the cylinder assembly 18 of the steamer 10 and are conveyed down the length of the cylinder by the auger 31 to the opposite end. Steam is introduced through the steam head on steam jets 26 at a typical temperature of from about 212° F. to about 338° F., more typically from about 220° F. to about 320° F., and most typically from about 260° F. to about 310° F. The whole watermelons are typically held inside the steamer from about 30 seconds to about 90 seconds, more typically from about 45 seconds to about 70 seconds, and most typically from about 55 seconds to about 60 seconds. As the whole watermelon travels through the steamer 10, the outside surface of the watermelon is softened and disinfected. The steaming of the outside surface removes microbials that otherwise may cause the watermelon extract to contain an unacceptable total plate count (TPC) of bacteria. It is presently believed that the fact that watermelon grows on the ground as opposed to in, for example, a tree, at least partially causes the increased tendency for higher bacteria levels in watermelon extract when the exterior of the melons are not steamed or otherwise cleansed prior to being subject to further processing in the extracting process.

After leaving the steamer 10, the whole watermelons are conveyed to a chopper 40. In operation, a motor 42 drives a cylindrical drum 44 with a plurality of teeth 46 mounted on the exterior portion of the cylindrical drum 44. A hopper 48 receives the whole watermelons and, through their weight and the teeth on the drum, the whole watermelons are reduced in size. The chopper 40 exerts pressure on the whole watermelon, essentially “crunching” it into pieces. The watermelon pieces formed by the chopper 40 typically include pieces of watermelon flesh only, pieces of watermelon rind only, and pieces of watermelon flesh and rind combined, as well as watermelon juice. Typically, the watermelon pieces are chopped into pieces smaller than about 16 inches square, more typically smaller than about 10 inches square, and most typically smaller than about 8 inches square. One chopper suitable for use may be purchased from Flo-Din. of Moses Lake, Wash. The watermelons are received by and/or otherwise conveyed to one or more receiving tanks 50.

Next, the watermelon pieces are conveyed from a receiving tank 50 to a first finisher 60. FIGS. 4, 5, 6 and 6A illustrate an embodiment of the first finisher 60. As shown in FIG. 4, the first finisher 60 generally includes vertical support members 62 and horizontal support members 64. The first finisher 60 further generally includes a receiving chamber 66 that receives the watermelon extract, and at least substantially cylindrical finishing chamber 68 that, along with the drive motor housing 70, houses the finishing cylinder assembly 72 and drive motor (not shown). The motor is typically an electrical motor or gas engine, or other powered actuator. Preferably, the drive for the motor or engine is a variable drive, more preferably a variable frequency drive. Preferably, the motor or engine engages the central shaft 76 of the finishing cylinder assembly 72 to drive rotation of the shaft when the finisher is in operation. One end of the shaft is typically mounted outside of the cylindrical finishing chamber 68 within the drive motor housing 70, typically to horizontal support member 78.

The finishing cylinder assembly 72 generally includes a cylindrical finishing screen 80, which cooperates with the finishing brushes 82 to extract the watermelon extract from the watermelon pieces. The finishing brushes 82 generally include brush support members 90, a body 92, and bristles 94. Typically, the central shaft 76 is at least substantially concentric, preferably concentric within the cylindrical finishing screen 80. Typically, the central shaft 76 has a plurality of radially extending members 84 spaced at substantially 90 degrees from one another, more typically 90 degrees. Preferably, the radially extending members 84 are engaged to central shaft collars 86 by a weld. The central shaft collars 86 engage the central shaft 76. The radially extending members 84 are typically threaded at the distal end 88. The distal end 88 engages brush support members 90, which themselves engage, typically by utilizing a nut 96 and bolt 98 assembly, to the finishing brushes 82 that, as discussed above, generally have a body 92 and bristles 94. Spacers and/or nuts between the brush support members 90 and the bodies 92 of the finishing brushes 82 operate to help regulate the amount of watermelon flesh that is removed from the rind. This can also conceivably be adjusted by adjusting the location of the brush support member 90 on the thread end of the radially extending members 84.

Each of the bristles 94 of the finishing brushes 82 are typically made of a synthetic fiber, such as nylon (a polyamide). Preferably, there are two sets of four at least substantially evenly spaced brushes, more typically spaced at 90 degree intervals about the rotating central shaft 76. Typically there are four brushes that run the length of the cylindrical finishing screen 80. Typically, the cylindrical finishing screen 80 has a total diameter of about 8 inches to about 32 inches, more typically from about 12 inches to about 30 inches, and most typically a diameter of about 24 inches. The distance from the tip bristles 94 of a finishing brush 82 to the surface of the cylindrical finishing screen 80 is from about ¾ inch to about 1 inch. Usually, the leading end of the brush 82 is about 1 inch from the cylindrical finishing screen 80 and the trailing end of the brush 82 is about ¾ inch from the cylindrical finishing screen. This allows for the preferred amount of flesh of the watermelon pieces to be removed from the rind.

Typically, watermelon pieces are introduced into the first finisher at one end of the first finisher (also called an “automated separator device” herein). As the watermelon pieces rotate inside the first finisher, the watermelon flesh attached to the rind substantially separates from the rind. At least a portion of watermelon flesh remains attached to the watermelon rind. Leaving a portion of watermelon flesh on the watermelon rind prevents rind from being removed. Typically, at least about 1/16 inch of watermelon flesh remains on the rind. Leaving at least about 1/16 inch of flesh on the rind generally prevents the undesired color and flavor from occurring in the watermelon extract. The amount of watermelon flesh left on the rind usually ranges from about 1/16 inch to about ¼ inch, more typically from about 1/16 inch to about 3/16 inch, and most typically about ⅛ inch.

To further prevent removal of too much watermelon flesh, the watermelon pieces should preferably be rotated in the first finisher 60 at a slow speed. Typically, the radially extending members 84 are operated at about 180 rpm to about 600 rpm, more typically about 220 rpm to about 450 rpm, and most typically about 260 rpm to about 300 rpm. The centrifugal force created by the rotating brush assembly 82 pushes watermelon flesh and juice through the cylindrical finishing screen 80. The mixture of watermelon flesh and juice may also include some seeds depending on the size of the apertures in the cylindrical finishing screen. The apertures 93 of the cylindrical finishing screen are about ¼ inch in diameter and are equally spaced about ½ inch from one another (measured from the center of each aperture to the center of the next most adjacent aperture).

The watermelon extract collects in the receiving chamber 66 of the first finisher. Once extracted in the first finisher 60, the extract is typically pumped to a second finisher 100. Typically, one end of the first finisher 60 is elevated, so that as the watermelon extract is obtained from the watermelon pieces, gravity helps the waste pieces to fall out the bottom end of the first finisher 60 and into a waste receiving bin or waste moving auger, which transports the waste away.

The second finisher 100 includes a cylindrical finishing screen with a finer mesh size than the screen in the first finisher 60 and uses centrifugal force to force the extract through the cylindrical screen of the second finisher. The second finisher 100 with the finer mesh cylindrical screen is used to remove any seeds present in the watermelon extract that may be present after the extract is initially obtained in the first finisher. While any finisher capable of removing seeds can be used, one finisher suitable for use in the process of the present invention is a BROWN™ Finisher, manufactured by Brown International Corp. of Covina California.

The watermelon extract is then typically sent to a filter device. The filter device 110 substantially separates the watermelon flesh from the watermelon juice in the extract. The filter device 110 may be any acceptable filter, such as a SERMIA™ filter, manufactured by Sermia International Inc. of Blainville, Quebec, Canada. The SERMIA™ filter is a rotary filter which operates with a gentle centrifugal effect at a variable speed and tilt angle for separation of the solid watermelon flesh in suspension in the watermelon extract. In early testing, the filter device 110 included a screen with openings of about 80 micron to about 100 micron, most preferably being an 80 micron screen. Further testing indicates that a filter will work that uses a screen of less than 80 micron up to a screen of about 0.020″ mesh size (which has approximately 510 micron size openings) depending on the desired through-put and quality required of the concentrate being made. Notably, screen sizes of 50 microns or less will remove red color in the watermelon such that most of the red color has been removed, which is undesirable in many watermelon juice products but which may be desirable in some watermelon juice products. After filtering, the watermelon extract typically includes less than about 2.5% watermelon flesh and more typically includes less than about 1.5% watermelon flesh.

From the filter device 110, the watermelon juice is typically placed in holding tanks 120 and 130. There, an edible acid is added to the watermelon juice to adjust the pH of the extract. The acid can be either an organic or inorganic acid. Typically, the acid is an organic acid, typically an FDA-approved organic acid, such as citric acid. An organic acid has been found to enhance the microbial stability of the watermelon extract. Before addition of the acid, the pH of the extract in the holding tanks 120 and 130 is about 4.6 to about 7.0. Organic acid is added to adjust the pH to about 4.2 or less. Typically, the final pH of the watermelon juice is about 3.0 to about 4.5, and more typically about 3.5 to about 4.2. Typically, from about 1 pound to about 5 pounds of organic acid per ton of raw fruit is added, more typically from about 2 pounds to about 4 pounds of organic acid per ton of raw fruit, and most typically about 2.5 pounds organic acid per ton raw fruit is added to the watermelon juice in holding tanks 120 and 130.

Once the desired pH level is achieved, the watermelon extract is sent to the evaporator 140. In the evaporator, the watermelon extract is heated to a minimum temperature of about 170° F. As the water evaporates from the extract, the water is removed under a vacuum until a predetermined Brix level is achieved, usually from about 68 to about 70 Brix such that when the essence, which has no Brix level, is returned, the end Brix level of about 65 Brix is obtained. Brix is the measurement by which the percentage by weight of soluble solids is expressed as the percent of sucrose in a solution. This measurement at 20° C. can be measured with a Brix hydrometer or with a refractometer calibrated to a Brix scale.

During a preheat stage of the evaporation process, water soluble, clear liquids, referred to as essence, are collected. Essence is the highly volatile low-esters which are the main flavor components of the watermelon juice. The strength of the essence is typically expressed in “fold” terms. For example, “100 fold” means 1 gallon of essence from 100 gallons of single strength juice. Typically, available essence is returned to the watermelon extract during the evaporation process.

After evaporation, the resulting watermelon concentrate is packaged and may optionally be frozen for storage.

The watermelon concentrate produced by the extraction process of the present invention is red in color and possesses a strong watermelon flavor identity, something obviously desired in this fruit-specific product. Unlike prior art watermelon concentrate products, the watermelon extract of the present invention does not possess a fishy odor or flavor. The fishy odor and flavor present in previous watermelon extracts are presently believed to be caused by fatty acids present in the watermelon rind. These fatty acids are generally the same as those found in fish and are what gives fish a “fishy smell.” Although additives, such as colorants, sweeteners (such as sugars and artificial sweeteners such as sucralose) and flavors can be added to mask any fishy odor or smell present, it has been discovered that because of the improved flavor of the watermelon juice product of the present invention, such additives are not necessary.

Substantial separation of the red flesh interior of the watermelon from the watermelon rind while leaving a portion of the red flesh interior on the rind is presently believed to be responsible for the superior red color and more true to fruit flavor and smell associated with the watermelon extract of the present invention.

Using a HUNTER™ colorimeter, the color of the watermelon juice can be measured. The measurement of color was done using the HUNTER™ L, A, B standard color scale described below. The following test method is used in this application and examples. HUNTER™ L, A, B values are standard color scale values that indicate differences in brightness, hue, and saturation using a standard color system. The color system utilizes L values to relate lightness and a combination of A and B values to relate hue and croma on a coordinate scale. A-values represent redness-greenness and B-values represent yellowness-blueness. L-values describe the degree of brightness, where a value of 100 equals white and that of 0 equals black. A-values describe the degree of redness, which increases with an increasing A-value. B-values describe the degree of yellowness, which increases with increasing B-value. Generally, samples are placed on the sample plane of the colorimeter (which is calibrated using standard tiles according to the manufacturer's instructions) where a 45 degree incident light from a quartz-halogen lamp (clear bulb) illuminates the sample. An optical sensor placed at 0 degrees (perpendicular to the sample plane) measures the reflected light. Values are reported using a standard HUNTER™ L, A, B color scale. The L value measures the “brightness” of the juice, the A value measures the “redness”, and the B value measures the “brown” in a juice. Using these values, different watermelon juices can be compared and contrasted on a quantitative basis providing real numbers in the comparison. Table 1 shows a comparison of the watermelon extract of the present invention as compared to a prior art watermelon product.

TABLE 1 Watermelon Extract Property Prior Art Cloudy Produced According to Measured Watermelon Juice the Present Invention Brix 61.90 56.6 Titratable acidity 1.54 1.59 pH 4.50 4.51 HUNTER ™ color at concentrate: L value 4.15 22.22 A value 17.11 35.73 B value 7.16 27.37

As shown in Table 1 above, the HUNTER™ color values showing the levels of brightness and red color in the prior art juice are very poor. An L value of 4.15 indicates a very dull color. An A value of 17.11 indicates very little red color associated with the juice. In reality, this analytical information points to more of an amber/yellow color typically associated with apple juice than watermelon juice. In contrast, the color results of the watermelon juice of the present invention show vastly greater brightness and red values. As can be seen in Table 1, the L value of the juice of the present invention is more than five times the L value of the prior art juice, more particularly 18.07 points higher. The A value of the juice of the present invention is twice the L value of the prior art, more particularly 18.62 points greater. The B value is 20.21 points higher in the watermelon extract of the present invention. Visually, the watermelon juice of the present invention is bright and red, just what one would expect in a quality watermelon juice. Typically, the watermelon juice of the present invention typically has an L value of about 19 to about 24, more typically from about 21 to about 23, and most typically about 22. The watermelon juice typically has an A value of from about 32 to about 37, more typically from about 34 to about 36, and most typically about 35. The watermelon juice typically has a B value of about 24 to about 30, more typically from about 26 to about 28, and most typically about 27.

The watermelon concentrate or other extract of the present invention typically contains a TPC of bacteria of less than about 10001 g, more typically less than about 7001 g, and most typically less than about 500/g watermelon juice.

Watermelon juice, juice (cloudy or clarified) concentrate, or other extract can be used in a myriad of food products, including beverages, sorbet, yogurt, sauces, salad dressings, fruit salad desserts, bakery fillings, candy, and bar mixes.

The process and watermelon juice concentrate as described herein is directed to a cloudy watermelon juice. However, those skilled in the art will appreciate that the process of the present invention can also be used to produce clarified watermelon juice.

To prepare clarified juice, the cloudy juice is typically strained using clean press cloths, a rotating screen, or a vibrating-type shaker screen. After straining, the juice may be further clarified using one of the following methods: enzymatic, bentonite, gelatin-tannin, and electrokinetic absorption. The enzymatic method involves heating the juice and then adding pectolytic enzymes, which break down the natural pectin in the juice. In the bentonite method, the juice is heated to approximately 190° F., held for a few seconds, and then cooled rapidly. Then, typically a mixture of equal parts of bentonite and filter aid are added to the juice. The heat treatment coagulates colloidal material in the juice. The bentonite/filter aid mixture causes the coagulated colloidal material to flocculate, which is then filtered. In the gelatin-tannin method, gelatin is dissolved in water and then added to the cloudy juice. The gelatin combines with the tannins in the juice to form a precipitate. The juice is clarified when the precipitate settles out and pulls suspended fruit material in the juice down with it. The electrokinetic adsorption method uses a cartridge filter. The cartridge filter provides electrokinetic adsorption and small-pore mechanical straining. The filter medium is composed of cellulose and polymer fibers, which impart a positive charge. After the juice is clarified, it is mixed with a filter aid, such as diatomaceous earth or siliceous powder. It is then filtered through a filter cloth or filter paper. The filter aid along with the fruit material separated during the clarification process is caught on the filter cloth or filter paper.

As shown generally in FIG. 8, the process of producing clarified watermelon concentrate 190 of the present invention generally utilizes the same process as producing cloudy watermelon extract up until the watermelon extract has passed through the second finisher 100. Thereafter, instead of proceeding to a filter and being processed further as generally shown in FIG. 1, the extract is moved to a decanter (hold tank) 200 and the waste product is placed in drums. Next, the liquid extract is centrifuged 210 and the waste returned to the decanter hold tank.

The product from the centrifuge is transported or otherwise moved to a first holding tank 215 where, as in the process for preparing a cloudy extract, an organic acid, typically citric acid, is added to lower the pH to at least about 4.2 or less, typically to about 4.0. Typically, the same amount of acid per ton of raw fruit as used in lowering the pH of cloudy extract is also used to lower the pH at this stage as well. The extract in holding tank 215 is typically moved to a second holding tank 220. About 3 oz. of a pectin enzyme, such as ADEX G enzyme, per 2,000 gallons of extract is added. The blend is held for about ½ hour.

Once treated with the pectin enzyme and the pH has been adjusted, the enzyme-treated extract is moved or otherwise transported to feed tank 230. The feed tank feeds the extract into a regeneration heat exchanger 240. The regeneration heat exchanger heats the extract to about 180° F., which causes the remaining cloudy portion of the extract to form discrete masses or clumps of cloudy material. The extract is then cooled to a temperature of from about 40° F. to about 50° F. The extract with the discrete masses is then passed through a diatomaceous earth (DE) filter 250, which removes the discrete masses from the extract. The thermal processing of the extract in the temperature line heater facilitates the removal of the cloudy portion of the extract by the diatomaceous earth filter by forming the larger masses of cloudy material. Thereafter, the clarified (colorless or at least substantially colorless) extract is then typically evaporated and packaged as discussed above regarding the production of the cloudy concentrate. The clarified extract typically has a Brix of about 65, a pH of from about 3.8 to about 4.5, an acidity of from about 1.0 to about 3.0% by weight as citric at 65 Brix. The clarity of the clarified extract is typically at least about 80% transmittance at 625 nm, 7.8 Brix. The color of the clarified extract is about 35% or less transmittance at 440 nm, 7.8 Brix. The total plate count of the clarified extract is typically less than about 500/g.

Testing has shown that the present apparatus and process can be used on melons other than watermelon, such as cantaloupe and other muskmelons, and honeydew melons. In such case, the machinery and process can be adapted/adjusted for the particulars of the melon being processed . . . such as by adjusting or changing the equipment to remove more (or less) flesh from the rind (including changing piece sizes of rind parts), adjusting or changing equipment for different processing speeds and for different levels of filtering to obtain a desired quality of juice product and adjusting the equipment for optimal operating temperatures and steam pressures for a particular fruit.

For cantaloupe melon, the same process can be used as described above. However, testing has shown that plugging of screens can be a problem and must be appropriately managed. For example, cantaloupe may be “green” on day 1, acceptably ripe on days 2-3, and overripe or rotten on day 4. “Green” cantaloupe may result in small balls that plug openings in a screen. “Overripe” cantaloupe may result in rind that is leathery such that it tends to generate long strips that plug openings in screens. This can be controlled in part by controlling a quality of melon put into the equipment, but also can be helped by providing screens with larger opening sizes, slower through-put, and lower operating temperatures. In particular, steaming the cantaloupe to remove bacteria may also need to be adjusted since cantaloupe tend to be affected by steam more quickly (due to their smaller size and also due to their thinner, different rind), such that the steam temperature, force, locations of application, and/or total time of steam treatment may need to be adjusted downward. The present apparatus and process for watermelon can be modified to deal with these items such as by providing a cutter or disintegrator that reduces the cantaloupe to pieces to a smaller size than watermelon. For cantaloupe, it is preferred that the chopped pieces be a maximum of 4″×6″×½″ in size, or more preferably be about 1″×1″×¼″ in size. The cantaloupe is moved to the disintegrator by an auger that is shaped and adapted to move the cantaloupe at a slower pace than watermelon and without unacceptable smashing, so that the pieces (including bits of rind) are not turned into a puree-like substance. Generally, a similar amount of flesh (i.e., about 1/16″) can be left on the cantaloupe rind (as compared to watermelon) when separating the flesh from the rind, but it is noted that perhaps slightly more flesh can be removed without compromising taste and juice quality. Notably, cantaloupe juice is not normally concentrated, such that the collected juice is placed in storage containers and frozen without concentrating steps. The cantaloupe piece is not heated in the evaporator. Applicants have found that the heat of the evaporator substantially eliminates the flavor of the juice.

For honeydew melon, the machinery and process are more similar to processing of watermelon. Nonetheless, even here, parameters and equipment potentially need to be adjusted or adapted for particular characteristics and properties of the honeydew melon. For example, honeydew melon break apart in a slightly different manner than watermelon. Honeydew melon generally break apart with less of an “exploding” action such as is found in watermelon. This is affected by ripeness of the melon, rind thickness, size of the fruit, and particular family types of honeydew melons, as well as by the faster effect of steam cleaning on the honeydew melon.

It is contemplated that other melons with rinds can be processed for extracting juice by the present apparatus and method through fine-tuning and adjusting the equipment and operating parameters, as discussed above.

In the foregoing description, it will be readily appreciated by those skilled in the art that modifications may be made to the invention without departing from the concepts disclosed herein. Such modifications are to be considered as included in the following claims, unless these claims by their language expressly state otherwise. 

What is claimed is:
 1. An apparatus for steaming melon, the apparatus comprising: a support structure having rollers; a cylinder assembly including a cylinder having apertures and a first end and a second end, the cylinder being rotatably supported on the rollers of the support structure, wherein the apertures are between 2 to 8 inches wide and 4 to 14 inches long; a motor which rotates the cylinder assembly; a plurality of open air steam jets directing steam through the apertures at a whole melon located inside the cylinder, wherein the open air steam jets are aligned with the apertures of the cylinder assembly; and an auger disposed inside the cylinder, such that rotation of the cylinder causes the auger to rotate and move a melon having a rind through the cylinder from the first end to the second end and wherein steam provided from the plurality of open air steam jets disinfects the rind of the melon as it moves through the cylinder.
 2. The apparatus of claim 1, wherein the plurality of open air steam jets are configured to directly apply steam to a melon within the inside of the cylinder using the plurality of open air steam jets and wherein the plurality of open air steam jets are unobstructed and the steam applied is within a temperature range of from 212° F. to 338° F. when applied against the whole melon and the open air steam jets are disposed on a plurality of steam lines that are arranged in parallel.
 3. The apparatus of claim 2, wherein the auger is configured to motivate the whole melon through the cylinder and wherein the plurality of open air steam jets are positioned on at least one steam line extending along a length of the cylinder that the melons travel.
 4. The apparatus of claim 3, wherein the at least one steam line comprises a center steam line with open air steam jets directed upward toward an interior of the cylinder assembly and two side steam lines with open air steam jets positioned at an angle relative to the center steam line and directed toward the interior of the steam cylinder assembly.
 5. The apparatus of claim 4, wherein the apertures are grouped into a plurality of spaced apart sets of apertures spaced circumferentially around the cylinder where each set of apertures forms a ring-shaped set of apertures and the ring-shaped sets of apertures are aligned with the open air steam jets such that the open air steam jets deliver steam through each aperture of the ring-shaped set of apertures aligned with the open air steam jets as the cylinder rotates.
 6. The apparatus of claim 3, wherein the apertures are circumferentially elongated, and wherein the cylinder is operably supported for rotation and wherein the plurality of steam lines are fed by a steam supply line at a plurality of locations on the at least one steam line.
 7. The apparatus of claim 2, wherein the steam jets are spaced along the length of the cylinder and direct the steam upwardly against the whole melon and wherein the apparatus further comprises at least one steam supply line configured to deliver steam to the plurality of open air steam jets.
 8. The apparatus of claim 2, wherein the cylinder is at least 18 feet long and at least 24 inches in diameter and the plurality of steam lines are spaced apart from one another.
 9. The apparatus of claim 1, wherein the support structure comprises a housing having a plurality of removable access doors, wherein the plurality of open air steam jets are positioned along a length of at least one steam line in a bottom quarter of the housing.
 10. The apparatus of claim 9, wherein the support structure further comprises a plurality of vertical supports and cross members that elevate and support the housing.
 11. The apparatus of claim 10, wherein the apertures are positioned around the circumference of the cylinder forming parallel, spaced apart rings of apertures wherein the parallel, spaced apart rings of apertures are 7 to 11 inches apart from one another.
 12. The apparatus of claim 11, wherein the apertures are circumferentially elongated.
 13. The apparatus of claim 1, wherein the apertures are circumferentially elongated.
 14. The apparatus of claim 13, wherein the apertures are between 2½ to 6 inches wide and 3⅛ to 11 inches long.
 15. A steaming apparatus for steaming one or more whole melons, comprising: a support structure having rollers; a steam cylinder assembly including a cylinder having a plurality of apertures and a first end and a second end, the cylinder rotatably supported on the rollers of the support structure; a motor for rotating; a plurality of spaced apart steam lines extending along a length of the side of the cylinder wherein the steam lines have a plurality of unobstructed steam jets that are spaced from the steam cylinder such that an open space is between the steam cylinder and the plurality of unobstructed steam jets and wherein the plurality of unobstructed steam jets are configured to directly apply steam through a plurality of apertures and contact a whole melon having a rind when a melon is located inside the cylinder; and wherein the plurality of apertures are grouped into a plurality of spaced apart sets of apertures spaced circumferentially around the cylinder where each set of apertures forms a ring-shaped set of apertures and the ring-shaped sets of apertures are aligned with corresponding unobstructed steam jets such that the corresponding unobstructed steam jets deliver steam through each aperture of the ring-shaped set of apertures aligned with the corresponding unobstructed steam jets as the cylinder rotates; and an internal auger disposed inside the cylinder, such that rotation of the cylinder causes the internal auger to rotate and move the whole melon as the whole melon moves through the cylinder from the first end to the second end and steam provided by the plurality of spaced apart steam lines disinfects the rind of the whole melon; and wherein the plurality of apertures are circumferentially elongated; and the plurality of apertures are positioned around the circumference of the cylinder forming parallel, spaced apart rings and the spaced apart rings of apertures are 7 to 11 inches apart from one another.
 16. The apparatus of claim 15, wherein the steam cylinder assembly is operably connected to a motor by a drive belt assembly that frictionally engages an outside surface of the steam cylinder assembly such that the steam cylinder assembly rotates in response to activation of the motor by engagement of the motor with the drive belt assembly.
 17. The apparatus of claim 15 wherein the plurality of apertures are between 2½ to 6 inches wide and 3⅛ to 11 inches long.
 18. A system for separating melon rind from melon flesh, the system comprising: a housing of a steam cylinder assembly; a melon and steam receiving cylinder positioned inside the housing, the melon and steam receiving cylinder having a longitudinal axis; a melon insertion end; a steamed melon delivery end opposite the melon insertion end; and a plurality of apertures along the longitudinal axis; a plurality of spaced apart steam jets positioned in the housing between an inner wall of the housing and an exterior wall of the melon and steam receiving cylinder directing steam delivered from the steam jets through the plurality of apertures of the melon and steam receiving cylinder and wherein the plurality of apertures along the longitudinal axis are from 2 inches to 8 inches wide and from 4 inches to 14 inches long; wherein the steam jets are in alignment with the apertures of the steam cylinder assembly; an auger disposed inside the melon and steam receiving cylinder, such that rotation of the melon and steam receiving cylinder causes the auger to rotate and move and disinfect a melon having a rind through the melon and steam receiving cylinder from the melon insertion end of the melon and steam receiving cylinder to the steamed melon delivery end of the melon and steam receiving cylinder; wherein the plurality of spaced apart steam jets are open air steam jets that are unobstructed and apply steam through the plurality of apertures along the longitudinal axis into direct contact with the melon located inside the melon and steam receiving cylinder as the melon traverses from the melon insertion end to the steamed melon delivery end; a chopper which receives whole melons from the steam cylinder assembly; the chopper chopping the whole melon into cubed melon pieces with melon flesh, melon rind and melon flesh; and a finisher which includes brushes which receive the cubed melon pieces and separates melon rind from melon flesh while leaving a predetermined depth of melon flesh attached to the melon rind.
 19. The system of claim 18, wherein the auger is a reverse auger and the melon and steam receiving cylinder is configured to be positioned at an angle within the housing of the steam cylinder assembly such that the melon insertion end is elevated higher than the steamed melon delivery end. 